Plasmids and method for obtaining viral particles

ABSTRACT

The present invention describes a viral RNA expression plasmid and a method for obtaining viral particles based on said plasmids comprising transfecting animal cells with an expression vector or a set of expression vectors capable of expressing a nucleoprotein and RNA-dependent polymerase RNA; and transfecting the animal cell with an expression vector or a set of expression vectors with nucleotide sequences encoding recombinant RNA molecules.

FIELD OF THE INVENTION

The present invention relates to the field of medicine, veterinary medicine, molecular biology, immunology and biotechnology, specifically, to the development of vaccines and adjuvants therefor, and treatments. The field of application of this invention mainly corresponds to the fish farming industry. More specifically, this invention relates to a viral RNA expression plasmid and a method for obtaining viral particles based on said plasmids.

BACKGROUND OF THE INVENTION

Infectious salmon anemia (ISA) is a disease that mainly affects Atlantic salmon (Salmo salar) causing huge losses in salmon farming worldwide (1, 14). The clinical signs of this disease are the presence of pale gills, ascites, hemorrhagic necrosis of the liver, splenomegaly, congestive gut and acute anemia (14). ISA was first reported in Norway in 1984 (28), later diagnosed in Canada (4), Scotland (27), United States (18), Faroe Islands (18) and Chile (16).

The etiological agent of this disease is a packaged pleomorphic virus between 45 and 140 nm of diameter, called Infectious Salmon Anemia Virus (ISAV), belonging to the Orthomixoviridae family (8). Its genome consists of 8 ssRNA of negative polarity (ns-RNA) that encode for 10 proteins and which have Untranslated Regions (UTRs) at both ends (26).

There is a limited knowledge about the functions of each ISAV protein performs. Bioinformatics evidence indicates that segments 1, 2 and 4 would encode for dependent RNA polymerase subunits (RpRd), analogous to PB2, PB1 and PA of Influenza A virus, respectively. Segment 3 encodes for NP protein, which has been reported to have the ability to bind ssRNA (2). As for Influenza, it has been proven that these four polypeptides relate to each one of the eight viral RNA segments to form Ribonucleoprotein complexes (RNPs) (23). These eight RNP units correspond to the minimum infectious unit required to initiate a cell infection (23). Segment 5 encodes for the Fusion protein (F), which has shown to be present on the surface of the viral membrane, allowing at the first steps of the infection, the fusion of the membrane of the viral particle with the cell endosome, allowing the release of the RNPs into cell cytoplasm (3). Segment 6 encodes for hemagglutinin-esterase protein (HE), which is also present on the viral surface and whose function is to bind a sialic acid residue located in the cell receptor (15). HE protein also has receptor-destroying activity (RDE, receptor destroying enzyme), favoring the release of new viral particles emerging from the cell membrane (21). Contrary to what is observed in hemagglutinin from Influenza A virus, whose stalk region is highly kept, it has been reported that ISAV's HE protein has a highly variable region towards the carboxy terminal end and adjacent to the transmembrane region, also known as Highly Polymorphic Region (HPR) (9). This HPR region encodes for 35 amino acids and, based on its high polymorphism 30 variants have been described in Europe, North America and Chile (30, 31, 32). One theory explains this variation as a deletion phenomenon from an ancestral strain present in the longest HPR region that is called HPRO (33). The first HPRO strain was identified in Scotland in wild salmon that did not show any clinical signs of ISA, being classified as an avirulent strain (34). In contrast, those strains presenting deletions in that zone are capable of developing virulent ISA-related clinical signs and mortality. It is suggested that segment 7 encodes for non-structural proteins analogous to NS1 and NS2 of influenza A virus (19). Finally, segment 8 encodes for a transcript containing two overlapping open reading frames (ORF, Open reading Frame). ORF1 encodes for the matrix protein (M), and ORF2 encodes for M2 protein. It has been shown that M2 protein is involved in the modulation of the type-I IFN response in conjunction with the NS1 protein (12).

As regards the Influenza Virus, detailed study of the virus has been possible as a result of the development of a reverse genetics system, which allows to manipulate the virus genome, being able to determine possible causes of virulence, as well as detailed study of each one of the functions of viral proteins (13). The most widely used reverse genetics system on Influenza virus is the plasmid-based system which allows to generate recombinant viruses from cloned cDNA. ISA Virus has 8 genomic RNAs transcribed under control of RNA polymerase I and the proteins making up the ribonucleoprotein complex under the command of RNA polymerase II are expressed (10, 24).

At the date there are no reports describing a successful reverse genetics system on ISAV. A relevant difficulty in generating a reverse genetics system is having the defined promoter for RNA polymerase I, which has not yet been described for Atlantic salmon. The difficulty lies in that promoters for RNA Polymerase I are strictly species-specific, they do not have a clear genetic structure and are in the IGS region of rDNA, which are vast (6). Identification of the sequences corresponding to the promoter for Pol I and its enhancers is hard work, considering that the IGS in the Salmo gender varies between 15-23 kb length (5). For this reason, and in view of the need of having a promoter with RNA Pol I characteristics, here we evaluate the capacity of the 571 pb ITS-1 region (Internal Transcribed Sequences) as previously described for Salmo salar (Atlantic salmon) (25). It has been recently described in nematodes, through bioinformatics analysis, that the ITS-1 region contains transcription promoter motifs and regulator motifs in which their function are not been demonstrated yet (29). It is suggested in this study that in the ITS-1 region of the rDNA, there are motifs having promoter characteristics and transcription regulators that have been conserved for millions of year of evolution, differing between species of the same gender, although they suggest the making of in vitro transcription assays to prove it.

The present invention shows that ITS-1 region of the rDNA of Atlantic salmon shows transcription promoter activity, which has conserved for millions of years; however, to confirm this assertion in vitro transcription essays had to be made.

In Chile and all other salmon farmers, there is the urgent need of figure out virulence factors, pathogenesis mechanisms of ISA virus, and an efficient vaccine against the only member of the Isavirus gender, the implementation of a plasmidal reverse genetics system allowing to generate recombinant ISA virus (ISAVr) becomes a necessity. With this goal, the challenge of developing a reverse genetics system for ISAV based on plasmids and using innovative elements, such as the use of salmon's ITS-1 region which has never been described as a promoter element. A choice that turned out to be key for the success of the systems that will be described below.

DESCRIPTION OF THE INVENTION

Although this methodology has been initially developed to obtain viral particles of the ISA virus, it has been also confirmed that in other species of upper vertebrates this expression system is successful for the production of RNA molecules without any additional nucleotides on their ends, which significantly broadens the usefulness of this technique. This way, with this expression system it is possible to obtain any desired protein or RNA, in a countless different cell types. An example thereof is this system's capacity to transcribe viral RNA at 12 hpt in a human KEK 293 cell line as well as in a ST swine cell line, incubated at 37° C. (98.6° F.).

Therefore, the present invention seeks to solve the technical problem of providing a molecular genetics system allowing to obtain functional viral particles from ns-RNA. Other purpose of this invention is to provide a method for expressing autogenic or exogenic proteins to the viral particle used, as well as to express nucleic acids of the interference ARN-type.

DETAILED DESCRIPTION OF THE INVENTION Cell Lines Used

ASK cells (www.atcc.org, CRL 2747), derived from Atlantic salmon kidney, were cultured in Leibovitz medium (L-15, Hyclone), supplemented with 50 μg/mL gentamicin), 10% bovine serum (SFB, Corning cellgro®, Mediatech), 6 mM L-glutamine (Corning cellgro®, Mediatech) and 40 μM β-mercaptoethanol (Gibco®, Life Technologies). RTG-2 cells (http://www.phe-culturecollections.org.uk, ECACC 90102529), derived from rainbow trout gonad tissue, were cultured in a minimum essential medium (MEM, Hyclone) supplemented with 50 μg/mL gentamicin, 10% SFB (Corning cellgro®, Mediatech), 10 mM L-glutamine (Corning cellgro®, Mediatech), 1% non-essential amino acids (Hyclone) and 10 mM HEPES (Hyclone). CSE-119 cells, derived from Coho salmon embryo (http://www.phe-culturecollections.org.uk, ECACC 95122019) were cultured in a minimum essential medium (MEM, Hyclone) supplemented with 50 pg/mL gentamicin, 10% SFB (Corning cellgro®, Mediatech), 2 mM L-glutamine (Corning cellgro®, Mediatech), 1% non-essential amino acids (Hyclone). The cell lines were raised at 60.8° F., without CO2, except for CSE-119.

HEK293 cells (ATCC CRL 1573), human embryonic kidney cells, were cultured in Eagle's Minimum Essential Medium (EMEM, Hyclone), supplemented with 50 μg/mL gentamicin, 10% FBS (Corning cellgro®, Mediatech), 10 mM L-glutamine (Corning cellgro®, Mediatech), 1% non-essential amino acids (Hyclone) and 10 mM HEPES (Hyclone). ST cells (www.atcc.org, CRL 1746) derived from swine testicles, were cultured in Eagle's Minimum Essential medium (EMEM, Hyclone) supplemented with 50 μg/mL gentamicin), 10% FBS (Corning cellgro®, Mediatech), 10 mM L-glutamine (Corning cellgro®, Mediatech), 1% non-essential amino acids (Hyclone) and 10 mM HEPES (Hyclone).

Purification of ISAV Viral Particles

Virus purification was performed from 40 mL of ASK cell supernatant infected with the ISAV901_09 strain. After 14 post infection days, the cell supernatant was taken and clarified at 1000×g for 20 minutes at 39.2° F. The supernatant was then ultracentrifuged at 133,200×g for 2 hours at 4° C. (39.2° F.) and the pellet obtained was suspended in 100 μL TNE buffer overnight, at 4° C. (39.2° F.). Then, the suspension was loaded into 4 mL of a 20% w/v sucrose mattress in TNE buffer, and was ultracentrifuged at 124,200×g for 2 hours at 4° C. (39.2° F.), and, finally, the resulting pellet was re-suspended in 50 μL of TNE buffer.

Viral RNA Extraction

Viral RNA extraction (vRNA) was performed from 50 μL of purified ISAV901_09 virus, using the commercial E.Z.N.A kit. Total RNA Kit II (Omega, Bio-Tek, Inc.), according to manufacturer's instructions. The purified RNA was then quantified by measuring absorbance at 260 nm through the Nanoquant Infinite M200 pro (TECAN, Austria) equipment, and a vRNA concentration of 2.7 μg/μL was obtained. The vRNA was stored at −80° C. (−112° F.), until its use.

Amplification of the Complete 8 IASV 901_09 Genomic Segments, Bioinformatics Analysis and Primer Design.

The sequences including the non-coding 5′ and 3′ UTR ends of the eight genomic segments of the publications by Fourrier et al., Kulshreshtha et al., and Merour et al., (11, 17, 20), were collected. These sequences correspond to two Scottish isolates (390/98 and 982/08), one Norwegian isolate (Glesvaer/2/90), two Canadian isolates (NBISA01 and RPC NB 98-049) and a Chilean one (ADL-PM 3205 ISAV). Multiple alignment was performed using the ClustalW2 program. Based on the analysis of the alignments, the universal primers were designed to amplify the 8 complete segments, including the 5′ and 3′ UTR regions of any ISAV strain (Table I).

RT-PCR

The viral RNA of ISAV901_09 (7) was obtained by extraction from purified virus; the cDNA of the eight genomic segments was obtained via RT-PCR. To this effect, the SuperScript™ One-Step RT-PCR System with Taq Platinum DNA Polymerase kit (Invitrogen) was used following manufacturer's instructions. In order to obtain the cDNA of each segment in the RT-PCR reaction, the primer F (forward) (10 μM) and the appropriate R primer (reverse) (Table I) and 50 ng viral RNA, were used.

TABLE 1 Primers for amplifying the 8 complete ISAV segments Primer F (forward) 5′ to 3′ primer R (reverse) 5′ to 3′ primer 1a AGCTAAGAATGGACTTTATATCAGAAAAC AACCTTCGAAGCCAAACAGATAG ACG 1b CAATATCAAGTCCGTTCGACGTGG AGTAAAAAATGGACATTTTATTGATTAAAAGTATC GTC 2 AGCAAAGAACGCTCTTTAATAACC AGTAAAAAATGCTCTTTTACTTATTAAAAAT 3 AGCAAAGATTGCTCAAATCCC AGTTAAAATTGCTCTTTTCTTTATTTG 4 AGCTAAGATTGGCTGTTTCAAGA AGTAAAAATTGGCTTTTTGGAAAA 5 AGTTAAAGATGGCTTTTCTAACAATTTT AGTAAAAATTGGCTATTTATACAATTAATAATG 6 AGCAAAGATGGCACGATTCA AGTAAAAAATGCACTTTTCTGTAAACG 7 AGCTAAGATTCTCCTTCTACAATGGA AGTAAAAATTCTCCTTTTCGTTTTAAA 8 AGCAAAGATTGGCTATCTACCA AGTAAAAAAAGGCTTTTTATCTTTTG

Sequencing

The cDNAs of the ISAV genomic segments were cloned in the pGEMT-easy vector (Promega), following manufacturer's instructions. Three clones of each plasmid were sequenced using universal primers for promoter T7 and SP6, in addition to internal primers for each segment, as described in Cottet et al (7).

The sequencing results were analyzed using the BioEdit Sequence Alignment Editor 7.1.3 program, and to confirm the identity of the sequences, a local alignment was made using the BLAST server. In addition, a multiple alignment, using the CLUSTALW2 server between the sequences obtained from the 3′ and 5′ UTR ends of all the ISAV901_09 segments, was made. Once the complete sequences of the 8 segments of ISAV901_09 (with the 3′ and 5′ UTR ends) were obtained, they were used to synthesize the ISAV901_09 genome (Genscript Co. USA), incorporating into its ends the cleavage sites for the Sapl enzyme, and, thus, avoiding errors in the subsequent cloning in the pSS-URG vector.

Design of the Universal pSS-URG Vector Plasmid

In order to have a plasmid allowing for the transcription of the ISAV vRNA, a cassette that was synthesized using advances in synthetic biology (Genscript Co.), and incorporated into the pUC57 plasmid, was designed. The new vector built was called pSS-URG (plasmid for Salmo Salar Universal Reverse Genetic). FIG. 1c shows the scheme of all of the elements required for a correct transcription of vRNAs. Arranged from left to right, it follows that: as a promoter, ITS-1 region of Salmo salar; the sequence of hammerhead rybozime; rybozime of the hepatitis Delta virus (δ); between the sequences of the two ribosomes are the cut sites for the Sap I distant cut enzyme (New England Biolabs), and, finally, the rabbit β-globin transcription terminator. This innovative design allows to insert any ISAV genomic segment, or any other nucleotidic sequence, without incorporating other sequences at vRNA's both ends. Then, each one of the 8 cDNAs of the complete ISAV segments were cloned in the Pss-URG plasmid. This way, a collection of plasmids called pSS-URG/1, pSS-URG/2, pSS-URG/3, pSS-URG/4, pSS-URG/5, pSS-URG/6, pSS-URG/7 and pSS-URG/8, is obtained (FIG. 1e ).

pSS-UGR/S6-NotI-HPR and pSS-UGR/S6-EGFP-HPR Vector

A construct was designed based on the pSS-URG vector having the complete sequence (including the 3′ and 5′ UTR ends) in antisense and inverted from segment 6 of ISAV 901_09. As a marker, the vector has additions, in frame, within the HPR region of segment 6, exactly nine nucleotides containing the restriction site for the NotI enzyme nt 1015 5′-gtagca[GCGGCCGCA]acatct-3′nt 1.036 (FIG. 2). The designed vector, called pSS-UGR/S6-NotI-HPR, was synthesized at GenScript Co., using pUC57 as basis. In order to generate the pSS-URG/S6-EGFP-HPR vector, the EGFP coding sequence was cloned into the pSS-UGR/S6-NotI-HPR vector using Not I restriction site of the HPR region (FIG. 2).

Vectors to Express PB2, PB1, PA and NP Proteins of ISAV901_09

From the ORFs of segments 1, 2, 3, and 4 of ISA virus 901_09 encoding for PB2, PB1, PA and NP, respectively, (ID N° 7, 8, 9, 10) and which are cloned in the pGemT-easy vector (7), high fidelity PCR with Pfx Platinum (Invitrogen) was performed. The primers used to amplify each one of the gens are shown in Table 2, which include cutting sites for Ncol, Smal and Xhol enzymes (New England biolabs). Cloning ORFs of PB2 and PA was made with Ncol and Xhol restriction enzymes, cloning of the ORF from PB1 was made with Smal and Xhol restriction enzymes, and that of the ORF encoding for NP was with Mlul and Xbal restriction enzymes. For the expression of PB2, PB1 and PA, the ORFs of segments 1, 2, and 3 were cloned in the pTriex3 vector (Novagen). On the other hand, for the expression of the NP protein, the ORF of segment 3 was cloned in the pCI-neo vector (Promega).

TABLE 2 Primers to amplify the PB2, PB1, PA and NP ORF of  ISAV901_09 for cloning CMV vectors. ORF 5′ to 3′ Primer F 5′ to 3′ primer R PB2 NcoI -ATGCCATGGACTTTATATCAGAA XhoI-CCGCTCGAGAACACCATATTCATC AACACGATCAGCG CATAGG PB1 SmaI-TCCCCCGGGAAACTCTAGTAGGTG XhoI-CCGCTCGAGAACACGCTTTTTCTTCTT AATCAC NP MluI-CGACGCGTCATGGCCGATAAAGGT XbaI-CGCTCTAGATCAAATGTCAGTGTCTTC ATGAC CTC PA NcoI-CATGCCATGGATAACCTCCGTGAA XhoI-CCGCTCGAGTTGGGTACTGACTGCAA TGCATAAACC TTTTC Ex Vivo Transcription Trial, ASK Cell Transfection Kinetics with pSS-URG/Seg6-NotI Vector

To test the functionality of the pSS-URG base vector, ASK cells were seeded at a density of 2.5×10⁴ cell/cm² per well in a 24-well plate (SPL) in Leibovitz Medium (L-15, Hyclone), supplemented with gentamicin (50 μg/mL) and 10% fetal bovine serum (SFB, Hyclone) being cultured at 18° C. (64.4° F.), until reaching 80% confluence. The cells were transfected with the pSS-URG/S6-NotI-HPR vector using Fugene 6 (Promega) at a 1:6 ratio, following manufacturer's specifications. The cells were incubated at 16° C. (60.8° F.) for 3 hours, the mixture being then removed and the cells washed 2 twice with PBS, starting with transfection kinetics that is at 0, 3, 6, 9, 12 and 15 hours. From each well, at each point of the kinetics, total RNA was extracted from the cells using E.Z.N.A. Total RNA Kit II (Omega, Bio-Tek), DNA was eliminated by using RQ-DNase treatment (promega). The RNA obtained was subjected to RT-PCR using primers for the NotI restriction site and the 5′UTR end of viral segment 6 (Table 3).

TABLE 3 Primers to amplify vRNA of S6-NotI Primer 5′ to 3 sequences′ F S6-NotI GTAGCAGCGGCCGCA R S6-5′UTR AGTAAAAAATGCACTTTTCTGAAACG

cDNA was obtained through reverse transcription (RT) using the M-MuLV Reverse Transcriptase enzyme (Moloney Murine Leukemia Virus Reverse Transcriptase, 200U/μL New England BioLabs). The reverse transcription mixture was made at a final 25 μL volume, in accordance with manufacturer's specifications. cDNA was then used to carry out a PCR reaction with DNA polymerase Paq5000 (Agilent Technologies). PCR products were visualized by electrophoresis at 90 volts for 1 hour on a 2% ethidium bromide-stained (10 mg/mL) agarose gel (FIG. 3).

Generation of Recombinant ISAV (ISAVr) Through Plasmid-Based Reverse Genetics System

ASK cells were seeded at a density of 2.5×10 4 cell/cm² on Nunc™ Lab-Tek™ II Chamber Slide™ System plates, and then incubated for 72 hours at 18° C. (64.4° F.). The cells were transfected with Fugene 6 (Promega) 1:6, in accordance with manufacturer's specifications. As for the generation of ISAVr⁹⁰¹ ^(_) ⁰⁹, a total of 250 ng of a mixture of vectors pTriex-3-PB2, pTriex-3-PB1, pTriex-3-PA and pCI-neo-NP and 1 μg of the total eight pSS-URG (pSS-URG/1-8) vectors. Recovery of the rISAVS6-NotI-HPR and rISAVS6-EGFP-HPR viruses was performed by replacing pSS-URG/6 with pSS-UGR/S6-NotI-HPR and pSS-URG/S6-EGFP-HPR, respectively. The cells were then incubated with 1 mL of L-15 medium, for 7 days at 16° C. (60.8° F.) (FIG. 4).

Infection of ASK Cells with ISAVr^(S6-EGFP-HPR)

ASK cells were seeded at a density of 2.5×10 4 cell/cm² per well, in 8-well Nunc™ Lab-Tek™ II Chamber Slide™ System plates, and were cultured at 16° C. (60.8° F.), until reaching 90% confluency. Then, the cells were washed with PBS twice, and blind passages were made with 100 μL of a 1:10 dilution of the supernatant either from passage 0 (P0) at 7 days post-transfection or from the different passages at 7 days post infection of ISAVrS6-EGFP-HPR in L-15 medium without SFB with gentamicin (50 μg/mL). The cells were incubated for 4 hours at 16° C. (60.8° F.), then washed twice with PBS and 500 μL of L-15 medium was added with 10% SFB and gentamicin (50 μg/mL), being then incubated for 7 days at 16° C. (60.8° F.). Each viral passage was obtained with this procedure every 7 days up to the fourth ISAVr^(S6-EGFP-HPR) passage, in addition to P0. The supernatant of each passage was stored at −20° C. , until further analysis thereof (FIG. 4).

ISAVr^(S6-EGFP-HPR) Detection

RNA extraction, RT-PCR and qRT-PCR in real time:

To detect ISAVr^(S6-EGFP-HPR,) a total RNA of 350 μL was extracted from the ASK cells' supernatant as transfected with the 12 plasmids at 7 post-transfection days (ISAVr^(S6-EGFP-HPRN)) or supernatants from the 1st to 4^(th) blind passages, with RNAv extracted from RNAv of segment 6, EGFP and Segment 6-EGFP being detected through RT-PCR.

Prior to the RT-PCR reaction, the RNA was treated with RNase-free DNase (Promega). For the reverse transcription reaction (RT), F-UTR-S6 primers (Table 1), F-S6 primers (Table 3), or EGFP primers (Table 4) were used, using the M-MLV RT enzyme (200 U/μL Promega), in accordance with manufacturer's specifications.

TABLE 4 Primers for the detection of vRNA from S6-EGFP-HPR Pri- mer 5′ to 3′ primer F 5′ to 3′ primer R S6 TGAGGGAGGTAGCATTGCAT AAGCAACAGACAGGCTCGAT EGFP CTGGAAGTTCATCTGCACCAC TGCTCAGGTAGTGGTTGTC S8 GAAGAGTCAGGATGCCAAGACG GAAGTCGATGAACTGCAGCGA

For PCR, the GoTaq® Green Master Mix kit (Promega) and Forward (S6 or EGFP) and Reverse (S6 or EGFP) primers were used. The thermal program used was: 95° C. for 2 minutes, 35 95° C. cycles for 30 seconds, 59,1 ° C. for EGFP, or 54° C. for S6 or S6-EGFP, 30 seconds, 72° C. for 30 seconds, and a final extension of 72° C. for 5 minutes. In all of the cases, re-amplification of the PCR products was carried out, using the same primers. The products of the PCR re-amplification were visualized via electrophoresis on 1% (w/v) agarose gel, run at 90 V for 45 minutes, and stained with ethidium bromide (10 mg/mL).

In order to detect the number of copies of the vRNA, a qRT-PCR was carried out in real time using the absolute method as described by Munir and Kibenge (22), a standard curve being made from the pSS-URG/S8 plasmid. The RT-PCR analysis in real time was carried out on the Eco Real-Time PCR System equipment (Illumina), using the SensiMix™ SYBR® Hi-ROX Kit (Bioline), following manufacturer's instructions, using the F-S8 and R-S8 primers (Table 4). The thermal profile used to amplify the region of segment 8 was 1 initial denaturation cycle of 10 minutes a 95° C., followed by 40 amplification cycles (15 seconds at 95° C., 15 seconds at 60° C., and 15 seconds at 72° C.). Following the amplification cycles, a dissociation cycle (30 seconds at 95° C., 30 seconds at 55° C., and 30 seconds at 95° C., was carried out. This procedure was performed for passage 4 of the recombinant virus. The results obtained were analyzed on EcoStudy software.

Confocal Microscopy

On the 7th post-infection day, ASK cells infested with rISAVS6-EGFP-HPR in each passage of the recombinant virus were analyzed via confocal microscopy, using the procedure as described by Rivas-Aravena et al. (45). The fixed cells were observed using a LSM 510 confocal microscope (Zeiss), utilizing the LSM image Browser software to detect rISAVS6-EGFP-HPR by visualizing EGFP fluorescence. In addition, rISAV was detected using anti-HE monoclonal antibody (BiosChile), as was already described (45).

Tagging by Lysis Plate Trial

ASK cells were seeded at a density of 2.5×10 4 cell/cm² per well of a 12-well plate (SPL) and were incubated at 16° C. until reaching 100% confluency. The ISAVr^(S6-EGFP-HPR) variant of Passage 4 was tagged. The procedure was performed as described by Castillo-Cerda et al (35).

ISAVr^(S6-EGFP-HPR) Fluorescence Quantification Trial

ASK cells were seeded at a density of 2.5×10 4 cell/cm ² per well, in a 48-well plate (SPL), and were incubated at 16° C. until reaching 100% confluency. Passage 4 of ISAVr^(S6-EGFP-HPR) was tagged. To this effect, serial dilutions of each viral inoculum were performed using a 10-dilution factor, from 10⁻¹ to 10⁻⁶ in L-15 medium, without FBS. The culture medium was then removed and 400 μL of viral inoculum was added to each well, and it was incubated at 16° C. for 4 hours to allow virus absorption. Subsequently, the inoculum was removed from each well, the cells were washed twice with PBS and, then, the L-15 medium was added, being supplemented with 10% SFB, 6mM L-glutamine (Corning cellgro®, Mediatech), 40 μM β-mercaptoethanol (Gibco®, Life Technologies), 50 μg/ml gentamicin. The plates were incubated for 7 days at 16° C. At the end of the infection, the supernatants from each well were analyzed, fluorescence being quantified using the Nanoquant Infinite M200 pro equipment (TECAN, Austria), exciting at 485 nm, and capturing the emission at 535 nm. These supernatants were also used for extracting total RNA and subsequent qRT-PCR, in real-time, to quantify the RNAv in ISAV segment 8, and for determining, this way, the number of copies of the cell culture from segment 8, as described above.

Infection Kinetics of ISAV901_09, ISAVr⁹⁰¹ ^(_) ⁰⁹, ISAVr^(S6/EGFP-HPR)

Infections of ASK cells were carried out with the fourth passage of ISAVr^(S6/EGFP-HPR), using the fourth passage of ISAVr⁹⁰¹ ^(_) ⁰⁹ as control, in addition to wild ISAV901_09. For each virus isolate, an infection was carried out with a MOI of 0.01. The infection kinetics was carried out by collecting samples at 0, 2, 4 and 7 days after the infection, then a RNA extraction, DNase treatment, and then a real-time qRT-PCR were carried out, to quantify RNAv of ISAV segment 8 of each cell culture supernatant (22).

Visualization of Particles

The ASK cells were seeded as indicated above and cultured at 16° C. until reaching 90% confluence. Cells were then infected with 400 μL of a 1:10 dilution of ISAVr^(S6/EGFP-HPR) virus in its 4th passage, or the 4th passage of rISAV⁹⁰¹ ^(_) ⁰⁹ or wild ISAV901_09 as control. Four days after infection, the cells were fixed with 2.5% glutaraldehyde in cacodylate buffer 0.1 M at pH 7.2 for 6 hours at room temperature, and then washed with sodium cacodylate buffer 0.1 M at pH 7.2 for 18 hours at 4° C. The samples were then fixed with 1% aqueous osmium tetroxide for 90 minutes, and then washed with distilled water and stained with an aqueous solution of 1% uranyl acetate for 60 minutes. Samples were then dehydrated with washes of 20 minutes each time with a series of buffers containing acetone 50, 70, 2×95 and 3×100%. Samples were finally embedded in epon resin/acetone at 1:1 ratio overnight, and then embedded in pure epon resin which was polymerized at 60° C. for 24 hours. Thin sections (60-70 nm) were obtained in ultramicrotome Sorvall MT-5000, and then mounted on copper grids, and then stained with 4% uranyl acetate in methanol for 2 min, and then citrate for 5 min. The samples were observed with a 12 to 80 kV electron microscope Philips Tecnai (FIG. 6).

DESCRIPTION OF THE FIGURES

FIG. 1: Obtaining the plasmids to allow transcription of the 8 RNAv of ISAV901_09: (1) pSS-URG plasmids and the plasmid containing each of the ISAV genome segments are digested with the Sapl restriction enzyme. The digestion products are visualized on a 1% agarose gel, and then purified. (2) The digested product corresponding to the ISAV genome segment and the linear pSS-URG plasmid are ligated with T4 ligase, and then this ligation is used to transform chemo-competent bacteria. (3) From the clones containing the expected recombinant plasmids, purification is carried out to confirm the correct insertion of the genome segment by sequencing.

FIG. 2: Schematic design of pSS-URG, pSS-URG/S6-NotI and pSS-URG/S6-EGFP-HPR cassettes. The universal vector contains the sequence of: promoter of S. salar (SS prom); hammerhead ribozyme (HH rib); hepatitis virus ribozyme δ(HDV rib); rabbit β-globin transcription terminator (Term). pSS-URG/S6-Not and pSS-URG/S6-EGFP-HPR plasmids contain the cDNA of antisense and inverted segment 6, which includes 5′ and 3′ UTRs and their modifications; NotI restriction site or the EGFP coding sequence.

FIG. 3: RT-PCR of the 6-NotI-HPR segment from ASK salmon cells transfected with pSS-URG/S6-Not-HPR plasmids. Agarose gel electrophoresis of RT-PCR products of segment 6 at selected post transfection times. ASK cells were transfected using Fugene 6 (Promega), the plasmid used was pSS-URG/segment 6.

FIG. 4: Reverse genetics to obtain recombinant ISA virus: ASK cells are transfected with 8 pSS-URG/S1-8 plasmids, which allow transcription of the 8 vRNA (ISAV genome), together with 4 plasmids that allow expression of the proteins that form the cRNP (PB2, PB1, PA and NP). Co-transfection of these 12 plasmids in the same cell to allow the formation of the 8 cRNP in the nucleus, which are the minimum unit required to form an ISAV viral particle. These cRNPs allow transcription and replication of the vRNA, allowing synthesis of all proteins that form the virus and the generation of new cRNPs, thus forming recombinant viral particles.

FIG. 5: RT-PCR of 6-NotI-HPR segment from ST swine cells (a) and HEK-293 human cells (b), both transfected with pSS-URG/S6-NotI-HPR plasmid using Fugene 6 (Promega). Agarose gel electrophoresis of RT-PCR products of segment 6 at selected post transfection times.

FIG. 6: Electron Microscopy Analysis of recombinant ISAV from sections of infected ASK cells. Cytoplasmic membrane with ISAV particles budding from infections with: (A) WT ISAV 901_09, (B) rISAVS6-EGFP-HPR and (C) rISAV 901_09. (D) Endosomal section showing rISAV 901_09 particles inside endosomes, which correspond to the initial steps of the fusion of viral and endosomal membranes. Bar: 200 nm.

EXAMPLES ISAV 901_09 Strain Genome Adapted to Cell Culture

The complete genome of a virus isolate adapted to cell culture, such as ISAV 901_09 (HPR 1c), was sequenced.

Alignments between the noncoding regions (UTR) of the 5′ and 3′ ends of complete sequences of the six ISAV isolates, two Scots (390/98 and 982/08), one Norwegian (Glesvr/2/90), two Canadian (NBISA01 and RPC NB 98-049), and one Chilean (ADL-PM 3205 ISAV) have high conservation at the ends of each viral genome segment, allowing to design universal primers described in Table I. The primers were used to amplify the genome of the Chilean ISAV 901_09 strain. The result of sequencing the eight viral genome segments is shown in Table IV. The sizes of the eight viral segments range from 2267 bp to 906 bp for segments 1 and 8, respectively.

The sequence of the 3′UTR regions ranged from 7 nucleotides in segment 6 to 48 nucleotides in segment 3, and there were no differences in the size of each 3′UTR end previously described for the 6 genomes analyzed, except for the addition of a nucleotide at the 3′UTR end of segment 7. The sequences of the 5′UTR ends of ISAV 901_09 range from 67 nucleotides in segment 4 to 147 nucleotides in segment 3. The alignment of the UTR regions also indicates that ISAV 901_09 has a high similarity with the ISAV Glesvr/2/90 strain (between 97% and 98% identity).

Universal Vector Design for ISAV Reverse Genetics

In order to achieve a vector which expresses segments of full-length viral RNA without additional nucleotides, taking advantage of advances in synthetic biology, an innovative design was made integrating elements previously used in reverse genetics of RNA viruses, such as Hammerhead ribozymes and delta (δ) hepatitis virus, together with genome elements of the Salmo salar species. The designed vector was called pSS-URG (plasmid for Salmo salar Universal Reverse Genetic). The correctly connected components contained by the vector and ordered from left to right are: As a promoter ITS-1 region of Salmo salar, a sequence of Hammerhead ribozyme, the ribozyme of delta (δ) hepatitis virus, and the sequences of the two ribozymes incorporate two cutting sites for Sap I enzyme (New England Biolabs), and finally incorporated as transcription terminator is rabbit beta globin terminator (FIG. 2). This vector would allow cloning, without incorporating additional sequences, any viral segment, through the use of a distant cut enzyme, such as Sap I. Thus, this study presents a vector to be the base of the reverse genetics system for the ISA virus.

Once the pSS-URG plasmid is synthesized, subcloning of the eight genome segments of ISAV was achieved from synthetic genomes using distant cut enzyme Sap I (Data not shown). In addition to cloning the eight viral segments, as a genetic marker and in order to prove that generated viruses are recombinant agents and do not correspond to a contamination of the procedure, two genetic elements were inserted in the HPR area of the universal vector containing segment 6. The first genetic variant corresponds to the insertion in the HPR area of a sequence of nine nucleotides with the cutting site for the NotI enzyme, calling this new vector pSS-URG/S6-NotI-HPR. A second genetic variant corresponds to the product of cloning the sequence which codes for EGFP using previously created NotI site, thus the new vector called pSS-URG/S6-EGFP-HPR is obtained.

Analysis of Functionality for pSS-URG Vector by Ex Vivo Transcription Trial

To determine whether all the elements included in the vector allow the expression of viral RNA in salmon cells, and due to the uncertainty of functionality of the promoter suggested in ITS-1 region of Salmo salar, ASK cells were transfected with pSS-URG/S6-NotI-HPR plasmid in an ex vivo transcription trial. To determine the existence of a transcription process, the functionality analysis was made by detecting the RNAV at times 0, 3, 6, 9, 12 and 15 after transfection (hpt) through RT-PCR. The reverse transcription reaction was made using a single first complementary to the Not I restriction site. Surprisingly, the analysis result can display a PCR product from three hpt, which increases in intensity until 15 hpt (FIG. 3). This result would indicate that from transfected pSS-URG/S6-NotI-HPR plasmid, the cell is generating an RNA having the NotI restriction site, and therefore ITS-1 region of Salmo salar corresponds to a promoter element. To prove the generation of a viral RNA without additional nucleotides, a RT-PCR was carried out with specific primers for each ribozyme, the results showed that it was not possible to obtain an amplification product with primers that recognize sequences of ribozymes in any point of kinetics, indicating that generated RNA has no additional regions, such as, for example, ribozymes (data not shown).

These results suggest the use of the ITS-1 region and the inclusion in pSS-URG vector to express any type of RNA inside the cells. For example, RNA can be expressed as interfering RNA, silencing RNA or also micro RNAs.

Obtaining Recombinant ISA Virus (ISAVr)

As it has been reported for Influenza virus, the functional minimum unit of the virus corresponds to the ribonucleoprotein (RNP) complex, which consists of viral RNA that is bound by multiple copies of NP and by the viral polymerase including PB1, PB2 and PA subunits. In order to form the RNP complexes in salmon cells, ORFs of segments 1 to 4 of ISAV901_09 were cloned into expression vectors commanded by the Cytomegalovirus promoter. Thus, using the pTriEx-3 vector (Novagen), ORFs of segments 1, 2 and 4 were cloned, obtaining pTRiex3-PB2, pTRiex3-PB1, pTRiex3-PA vectors. Besides, using the pCI-neo vector (Promega), segment 3 was cloned generating pCI-neo-NP vector (Data not shown). Transfection of these vectors into salmon cells allows expression of recombinant proteins PB2, PB1, PA and NP, respectively.

Generation of ISAVr^(S6-NotI-HPR)

For the generation of ISAVr^(S6-NotI-HPR), ASK cells were cotransfected with twelve plasmids, four of which correspond to expression vectors pTRiex 3-PB2, pTRiex 3-PB1, pTRiex 3-PA and pCI-neo-NP, and the remaining eight correspond to plasm ids for pSS-URG reverse genetics with each of the eight genome segments of ISAV901_09 as DNA, replacing native segment 6 by Seg6-NotI-HPR. In order to amplify and determine the presence of recombinant virus, after transfection of cells, two blind passages were made in ASK cells infecting with the supernatants obtained from the previous transfections. On the one hand, the presence of RNAV of segment 6 (NotI/HPR) was detected, through RT-PCR, obtaining a product of an expected 306 bp size, both in the RNA extracted from the transfection supernatant and from the two subsequent passages, which suggests the presence of infectious viruses. The second passage supernatant was used to infect a greater amount of ASK cells. From the infected cells, which showed an obvious cytopathic effect (data not shown), the recombinant virus was visualized by transmission electron microscopy. FIG. 6 shows spherical particles similar to virus with diameters near 100 nm, which suggests that these correspond to the recombinant viruses. Therefore, it was possible to detect a recombinant ISAVr^(S6-notI-HPR) virus in infected cells, with replicative activity and reproducible cytopathic effect in passages subsequent to their generation.

Generation of ISAVr^(S6-EGFP-HPR)

In order to generate recombinant ISA virus containing a reporter gene, such as EGFP, in order to facilitate ex vivo monitoring and discard that results are artifactual results or contamination, ASK cells were co-transfected with twelve plasmids simultaneously: four of them correspond to expression vectors pTRiex3-PB2, pTRiex3-PB1, pTRiex3-PA and pCl-neo-NP; the remaining eight plasmids correspond to vectors pSS-URG/1, pSS-URG/2, pSS-URG/3, pSS-URG/4 , pSS-URG/5 , pSS-URG/7 and pSS-URG/8; also incorporating segment 6 with vector pSS-URG/S6-EGFP-HPR; the virus which contains EGFP in the HPR area of the protein is called ISAVr^(S6-EGFP-HPR).

To determine whether recombinant viral particles were generated after transfection, the culture supernatant (passage 0, P0) was analyzed 7 days after transfection (dpt). For this purpose, it was initially detected by RT-PCR RNAv of Segment 6, as well as the EGFP coding sequence in a second PCR product, and finally an area containing both part of Segment 6 and the EGFP. The results showed that RT-PCR products for Segment 6 have a different migration distance of the PCR products for the native virus (−300 bp) and the recombinant virus having EGFP in the HE protein (1,000 bp). The RT-PCR of the EGFP coding sequence has a ˜500 bp product, which is not observed in the native virus analyzed. For RT-PCR of S6-EGFP, an amplification product of −800 bp was obtained for the recombinant virus as expected.

Infectivity of ISAVr^(S6-EGFP-HPR) in ASK Cells

To determine whether the supernatant of ASK cells transfected with twelve plasmids indeed contains the viral variant ISAVr^(S6-EGFP-HPR) with the characteristics of an infectious agent, EGFP fluorescence was used as a reporter. The ASK cells infected with the supernatant that would contain the first progeny ISAVr^(S6-EGFP-HPR) were analyzed under confocal microscope 7 days after infection. The results show that it is possible to visualize cells emitting green fluorescence attributable to EGFP, corresponding to the first passage of the ISAVr^(S6-EGFP-HPR) virus. Distribution of the EGFP mark is found mainly in the cytoplasm and towards the plasma membrane, fluorescence being not observed in the cell nucleus. To confirm that the supernatant of transfected cells (passage 0) contains the ISAVr^(S6-EGFP-HPR) virus with lytic capacity, a lysis plaque trial was carried out on ASK cells. The result of the lysis plaque trial showed that the recombinant virus has the ability to generate lysis plaques like the wild virus, obtaining a virus titre in the order of 1×10⁴ PFU/m L.

Stability of lSAVr^(S6-EGFP-HPR)

Subsequently, the ability of this recombinant virus to maintain infectiousness and fluorescence was assessed in cell culture. Four blind passages of infection in ASK cells were carried out with 7-day gaps. Then, in each supernatant of the recombinant virus passages, a RT-PCR was carried out to detect RNAv both of Segment 6 and of the coding sequence for EGFP, and a region of the EGFP-S6 hybrid sequence. The result made possible to visualize a PCR product of 500 bp EGFP and EGFP-S6 hybrid sequences of 800 bp, indicating the presence of segment 6 containing the EGFP gene in all supernatants analyzed. The PCR product of segment 6 shows a 300 bp product in the supernatant of infected ASK cells with ISAV901_09 wild virus, as expected, in contrast to the 1,000 bp of the PCR product obtained in each of the four passages of ISAVr^(S6-EGFP-HPR) virus, whose larger size is the result of having incorporated the EGFP gene in segment 6.

To determine that each of the four passages not only had a virus with infectivity, but also was capable of fluorescing, indicating the correct folding of HE with EGFP in the HPR area, an analysis was carried out by confocal microscopy in infected ASK cells. Confocal microscopy showed cells that emit green fluorescence in all passages analyzed, increasing in each passage the abundance of fluorescent cells. These results suggest that the region of the HE protein elected to incorporate EGFP is not affected by the incorporation of this ORF, thus allowing the generation of a chimeric recombinant ISA virus capable of replicating, infecting and spreading in multiple passages without losing the ability to fluoresce. Titration of the fourth blind passage made to ISAVr^(S6-EGFP-HPR) virus by qRT-PCR in real time resulted in a titre of 3.63×10⁶ copies Seg 8/mL and a value of 6.5×10⁵ PFU/mL obtained by lysis plaque trial, showing a lysis plaque size similar to that observed after conducting plaque trial on ISAV901_09 wild virus.

Infectivity of ISAVr^(S6-EGFP-HPR) in salmonid cell lines

In order to determine whether by incorporating a sequence in the HPR area of the ISAVrs6-EGFP-HPR virus, this acquires the ability to infect other salmonid species or lose infectivity in permissive cells (ASK cells), an infection kinetics was carried out in RTG-2, CSE-119 and ASK cells. The ex vivo trial was conducted for 7 days using the fourth passage of the fluorescent recombinant virus and compared to the ISAV901_09 wild virus, and the fourth passage of a wild recombinant virus generated for this trial rISAV⁹⁰¹ ^(_) ⁹ (MOI of 0.01). The analysis at 0, 2, 4 and 7 dpi by qRT-PCR quantifying the number of copies of segment 8 in each supernatant showed that none of the three viruses analyzed had the ability to replicate in RTG-2 cells or in CSE-119 cells.

In contrast, the infection kinetics carried out on ASK cells showed that initially the ISAV 901_09 virus has a larger number of copies than recombinant viruses, rISAV⁹⁰¹ and rISAV^(S6-EGFP-HPR). On the second day after infection, however, an increase occurs in the number of copies of the recombinant viruses, reaching titres near 1,000 segment 8/mL, with values similar to the wild virus. These results suggest that the incorporation of EGFP in the HPR area of HE protein does not alter the replicative behavior of the fluorescent recombinant virus in ASK cells, and does not extend the host range at least in the ex vivo trials in RTG-2 cells or in CSE-119 cells.

These results can lead to the conclusion that it is possible to incorporate into the pSS-URG plasmid a sequence encoding both for a viral protein and for an exogenous or chimeric protein, thus achieving the generation of a modified or chimeric recombinant ISA virus; these modifications would not alter or affect its infectious or propagation characteristics.

Functionality of pSS-URG Plasmid in Salmon, Swine and Human Cell Lines

To determine the ability of the pSS-URG/S6-NotI-HPR vector for transcribing segment 6 as RNAv, it was transfected into ASK cells using Fugene 6 (Promega) at a 1:6 ratio and according to manufacturers' specifications. 0 hpt is considered as the time when adding the transfection mix to the cells. The initial incubation takes place for 3 hours at 16° C. F. Once the incubation time had elapsed, the transfection mix was removed and the cells were washed twice with PBS, this being a 3-hpt time. At each point of the transfection kinetics, which occurs at 0, 3, 6, 9, 12 and 15 hpt, the cells are removed for extraction of total RNA, possible contaminating DNA was removed with DNase I. With the RNA obtained, RNAv of segment 6 NotI was detected by RT-PCR using specific primers for segment 6 NotI. The analysis allows to observe a PCR product of expected 306 bps size from 3 hpt, which increases in intensity until 15 hpt (FIG. 3). Therefore, it is proved that the pSS-URG plasmid is functional.

Surprisingly, the ability to transcribe the viral RNA is not restricted to salmon cells cultured at 16° C. Using the same procedure (with incubations at 37° C.), but conducted only at 12 hpt, functionality was observed in human cell line HEK 293 and swine cell line ST, incubated at 37° C. (FIG. 5). This is reflected in obtaining a RT-PCR product of the expected size which allows to conclude that the vector is functional in salmon cell lines incubated at 16° C. and mammal cell lines incubated at 37° C., being this a tool that would allow the expression of any RNA in cells or tissues of vertebrate animals, whether cold-blooded or warm-blooded.

ISAVr^(S6-EGFP-HPR): Correlation Between the Number of Viral Copies and Measured Fluorescence

Since the ISAVr^(S6-EGFP-HPR) virus has similar characteristics to the wild virus when infecting ASK cells, and also has the advantage of monitoring the infection by incorporating EGFP as reporter, the goal is to determine whether there is correlation between the viral load and fluorescence in the supernatant of infection caused by this recombinant virus. The analysis carried out on serial dilutions of fluorescent recombinant virus through qRT-PCR and fluorescence quantitation established that there is a direct relationship showing an increased fluorescence detected when the viral titer of the solution increases, showing a fluorescence intensity of 500 units/mL for a titer of 2×10⁶ copies/mL.

REFERENCES

-   1. Asche, F., H. Hansen, R. Tveteras, and S. Tveteras. 2009. The     salmon disease crisis in Chile. Marine Resource Economics     24:405-411. -   2. Aspehaug, V., K. Falk, B. Krossoy, J. Thevarajan, L. Sanders, L.     Moore, C. Endresen, and E. Biering. 2004. Infectious salmon anemia     virus (ISAV) genomic segment 3 encodes the viral nucleoprotein (NP),     an RNA-binding protein with two monopartite nuclear localization     signals (NLS). Virus Res 106:51-60. -   3. Aspehaug, V., A. B. Mikalsen, M. Snow, E. Biering, and S.     Villoing. 2005. Characterization of the infectious salmon anemia     virus fusion protein. J Virol 79:12544-12553. -   4. Bouchard, D., W. Keleher, H. M. Opitz, S. Blake, K. C. Edwards,     and B. L. Nicholson. 1999. Isolation of infectious salmon anemia     virus (ISAV) from Atlantic salmon in New Brunswick, Canada. Dis     Aquat Organ 35:131-137. -   5. Castro, J., L. Sanchez, P. Martinez, S. D. Lucchini, and I.     Nardi. 1997. Molecular analysis of a NOR site polymorphism in brown     trout (Salmo trutta): organization of rDNA intergenic spacers.     Genome/National Research Council Canada=Genome/Conseil national de     recherches Canada 40:916-922. -   6. Comai, L. 2004. Mechanism of RNA Polymerase I Transcription, p.     123-155. In C. C. Ronald and C. Joan Weliky (ed.), Advances in     Protein Chemistry, vol. Volume 67. Academic Press. -   7. Cottet, L., M. Cortez-San Martin, M. Tello, E. Olivares, A.     Rivas-Aravena, E. Vallejos, A. M. Sandino, and E. Spencer. 2010.     Bioinformatic analysis of the genome of infectious salmon anemia     virus associated with outbreaks with high mortality in Chile. J     Virol 84:11916-11928. -   8. Dannevig, B. H., K. Falk, and E. Namork. 1995. Isolation of the     causal virus of infectious salmon anaemia (ISA) in a long-term cell     line from Atlantic salmon head kidney. J Gen Virol 76 (Pt     6):1353-1359. -   9. Devold, M., K. Falk, B. Dale, B. Krossoy, E. Biering, V.     Aspehaug, F. Nilsen, and A. Nylund. 2001. Strain variation, based on     the hemagglutinin gene, in Norwegian ISA virus isolates collected     from 1987 to 2001: indications of recombination. Dis Aquat Organ     47:119-128. -   10. Fodor, E., L. Devenish, O. G. Engelhardt, P. Palese, G. G.     Brownlee, and A. Garcia-Sastre. 1999. Rescue of influenza A virus     from recombinant DNA. J Virol 73:9679-9682. -   11. Fourrier, M., S. Heuser, E. Munro, and M. Snow. 2011.     Characterization and comparison of the full 3′ and 5′ untranslated     genomic regions of diverse isolates of infectious salmon anaemia     virus by using a rapid and universal method. J Virol Methods     174:136-143. -   12. Garcia-Rosado, E., T. Markussen, O. Kileng, E. S. Baekkevold, B.     Robertsen, S. Mjaaland, and E. Rimstad. 2008. Molecular and     functional characterization of two infectious salmon anaemia virus     (ISAV) proteins with type I interferon antagonizing activity. Virus     Res 133:228-238. -   13. Garcia-Sastre, A., and P. Palese. 1993. Genetic manipulation of     negative-strand RNA virus genomes. Annu Rev Microbiol 47:765-790. -   14. Godoy, M. G., A. Aedo, M. J. Kibenge, D. B. Groman, C. V.     Yason, H. Grothusen, A. Lisperguer, M. Calbucura, F. Avendano, M.     Imilan, M. Jarpa, and F. S. Kibenge. 2008. First detection,     isolation and molecular characterization of infectious salmon     anaemia virus associated with clinical disease in farmed Atlantic     salmon (Salmo salar) in Chile. BMC Vet Res 4:28. -   15. Hellebo, A., U. Vilas, K. Falk, and R. Vlasak. 2004. Infectious     salmon anemia virus specifically binds to and hydrolyzes     4-0-acetylated sialic acids. J Virol 78:3055-3062. -   16. Kibenge, F. S., O. N. Garate, G. Johnson, R. Arriagada, M. J.     Kibenge, and D. Wadowska. 2001. Isolation and identification of     infectious salmon anaemia virus (ISAV) from Coho salmon in Chile.     Dis Aquat Organ 45:9-18. -   17. Kulshreshtha, V., M. Kibenge, K. Salonius, N. Simard, A.     Riveroll, and F. Kibenge. 2010. Identification of the 3′ and 5′     terminal sequences of the 8 rna genome segments of European and     North American genotypes of infectious salmon anemia virus (an     orthomyxovirus) and evidence for quasispecies based on the     non-coding sequences of transcripts. Virol J 7:338. -   18. Lovely, J. E., B. H. Dannevig, K. Falk, L. Hutchin, A. M.     MacKinnon, K. J. Melville, E. Rimstad, and S. G. Griffiths. 1999.     First identification of infectious salmon anaemia virus in North     America with haemorrhagic kidney syndrome. Dis Aquat Organ     35:145-148. -   19. McBeath, A. J., B. Collet, R. Paley, S. Duraffour, V.     Aspehaug, E. Biering, C. J. Secombes, and M. Snow. 2006.     Identification of an interferon antagonist protein encoded by     segment 7 of infectious salmon anaemia virus. Virus Res 115:176-184. -   20. Merour, E., M. LeBerre, A. Lamoureux, J. Bernard, M. Bremont,     and S. Biacchesi. 2011. Completion of the full-length genome     sequence of the infectious salmon anemia virus, an aquatic     orthomyxovirus-like, and characterization of mAbs. J Gen Virol     92:528-533. -   21. Muller, A., S. T. Solem, C. R. Karlsen, and T. O.     Jorgensen. 2008. Heterologous expression and purification of the     infectious salmon anemia virus hemagglutinin esterase. Protein Expr     Purif 62:206-215. -   22. Munir, K., and F. S. Kibenge. 2004. Detection of infectious     salmon anaemia virus by real-time RT-PCR. J Virol Methods 117:37-47. -   23. Neumann, G., G. G. Brownlee, E. Fodor, and Y. Kawaoka. 2004.     Orthomyxovirus replication, transcription, and polyadenylation. Curr     Top Microbiol Immunol 283:121-143. -   24. Neumann, G., T. Watanabe, H. Ito, S. Watanabe, H. Goto, P.     Gao, M. Hughes, D. R. Perez, R. Donis, E. Hoffmann, G. Hobom, and Y.     Kawaoka. 1999. Generation of influenza A viruses entirely from     cloned cDNAs. Proc Natl Acad Sci U S A 96:9345-9350. -   25. Reed, K. M., J. D. Hackett, and R. B. Phillips. 2000.     Comparative analysis of intra-individual and inter-species DNA     sequence variation in salmonid ribosomal DNA cistrons. Gene     249:115-125. -   26. Rimstad, E., and S. Mjaaland. 2002. Infectious salmon anaemia     virus. APMIS 110:273-282. -   27. Rowley, H. M. C. S. J., Curran W. L. , Turnbull T.,     Bryson D. G. 1999. Isolation of infectious salmon anaemia virus     (ISAV) from Scottish farmed Atlantic salmon, Salmo salar L. Journal     of Fish Diseases 22:483-487. -   28. Thoroud K., D. H. O. 1988. Infectious salmon anemia in atlantic     salmon (salmo salar L.). European Association of Fish Pathologists     8:109-111. -   29. Van Herwerden, L., M. J. Caley, and D. Blair. 2003. Regulatory     motifs are present in the ITS1 of some flatworm species. Journal of     Experimental Zoology Part B: Molecular and Developmental Evolution     296B:80-86. -   30. Nylund A, Plarre H, Karlsen M, Fridell F, Ottem K F, Bratland A,     Saether P A. 2007. Transmission of infectious salmon anaemia virus     (ISAV) in farmed populations of Atlantic salmon (Salmo salar). Arch     Virol 152:151-179. -   31. Kibenge F S, Godoy M G, Wang Y, Kibenge M J, Gherardelli V,     Mansilla S, Lisperger A, Jarpa M, Larroquete G, Avendano F, Lara M,     Gallardo A. 2009. Infectious salmon anaemia virus (ISAV) isolated     from the ISA disease outbreaks in Chile diverged from ISAV isolates     from Norway around 1996 and was disseminated around 2005, based on     surface glycoprotein gene sequences. Virol J 6:88. -   32. Christiansen D H, Ostergaard P S, Snow M, Dale O B,     Falk K. 2011. A low-pathogenic variant of infectious salmon anemia     virus (ISAV-HPRO) is highly prevalent and causes a non-clinical     transient infection in farmed Atlantic salmon (Salmo salar L.) in     the Faroe Islands. J Gen Virol 92:909-918. -   33. Mjaaland S, Hungnes O, Teig A, Dannevig B H, Thorud K,     Rimstad E. 2002. Polymorphism in the infectious salmon anemia virus     hemagglutinin gene: importance and possible implications for     evolution and ecology of infectious salmon anemia disease. Virology     304:379-391. -   34. Cunningham C O, Gregory A, Black J, Simpson I, Raynard     R S. 2002. A novel variant of the infectious salmon anaemia virus     (ISAV) haemagglutinin gene suggests mechanisms for virus diversity.     Bull Eur Assoc Fish Pathol 22:366-374. -   35. Castillo-Cerda M T, Cottet L, Toro-Ascuy D, Spencer E,     Cortez-San Martin M. 2013. Development of plaque assay for Chilean     Infectious Salmon Anaemia Virus, application for virus purification     and titration in salmon ASK cells. J Fish Dis. 

What is claimed:
 1. A method of producing a chimeric ns-RNA virus, comprising: a) transfecting animal cells with an expression vector or a set of expression vectors capable of expressing a nucleoprotein and RNA-dependent polymerase RNA; b) transfecting the animal cell of a) with an expression vector or a set of expression vectors with nucleotide sequences encoding recombinant RNA molecules.
 2. The method of claim 1, wherein the cells are cultured under conditions suitable for cell replication of the transfected cells.
 3. The method of claims 1 and 2, wherein functional recombinant virus particles are obtained.
 4. A functional recombinant plasmid in animal cells, comprising a pSS-URG skeleton into which genome sequences of viruses that are expressed as RNA can be introduced.
 5. A functional recombinant plasmid in animal cells according to claim 4, wherein said plasmid is functional in animal cells.
 6. A functional recombinant plasmid in animal cells according to claim 4, wherein the pSS-URG plasmid contains the promoter sequence of S. salar found in the ITS-1 region; sequence of the Hammerhead ribozyme; a cloning site; sequence of the hepatitis δ virus ribozyme; and the rabbit β-globin transcription terminator.
 7. A functional recombinant plasmid in animal cells according to claims 4 to 6, wherein the promoter of S. salar has a sequence ID no:1
 8. A functional recombinant plasmid in animal cells according to claims 4 to 6, wherein the sequence of Hammerhead ribozyme has a sequence ID no:2.
 9. A functional recombinant plasmid in animal cells according to claims 4 to 6, wherein the cloning site has a sequence ID no:3.
 10. A functional recombinant plasmid in animal cells according to claims 4 to 6, wherein the sequence of the hepatitis δ virus ribozyme has a sequence ID no:4.
 11. A functional recombinant plasmid in animal cells according to claims 4 to 6, wherein the transcription terminator of the rabbit β-globin has a sequence ID no:5.
 12. A functional recombinant plasmid in animal cells according to claims 4 to 11, wherein said plasmid allows cloning genetic sequences of an animal, plant, protist, fungal, bacterial or viral origin using the distant cut restriction enzyme Sapl.
 13. A functional recombinant plasmid in animal cells according to claims 4 to 12, wherein said plasmid is transfected into an animal cell allowing gen transcription, obtaining an RNA without additional nucleotides at its ends.
 14. An expression plasmid, comprising encoding of necessary proteins to generate the cRNP.
 15. An expression plasmid according to claim 14, wherein sequences PB2 ID no: 7, PB1 ID no: 8, PA ID no: 9 and NP ID no: 10 of ISAV 901_09 are cloned separately.
 16. A method of obtaining viral particles, comprising: a) transfecting animal cells with an expression vector or a set of expression vectors capable of expressing a nucleoprotein and RNA-dependent polymerase RNA, sequences PB1 ID no: 7, PB2 ID no: 8, PA ID no: 9 and NP ID no: 10 of ISAV901-09. b) transfecting the animal cell of a) with an expression vector or a set of expression vectors pSS-URG with nucleotide sequences encoding recombinant RNA molecules under the control of the promoter sequence of S. salar found in the ITS-1 region; sequence of Hammerhead ribozyme; a cloning site; sequence of the hepatitis δ virus ribozyme; and the rabbit β-globin transcription terminator; c) Obtaining recombinant viral particles.
 17. Use of viral particles, comprising use to express RNA type nucleic acids.
 18. Use of viral particles according to claim 17, wherein such particles are used to express proteins that are autologous or exogenous to the virus.
 19. Use of viral particles according to claim 17, wherein such particles are used to express interfering RNA, silencing RNA or microRNA nucleic acids. 